CN112768959B - Antenna assembly and electronic equipment - Google Patents

Abstract

The application discloses an antenna assembly and electronic equipment, wherein the antenna assembly comprises a first antenna unit, a second isolation device and a first proximity sensing device, the first antenna unit comprises a first radiator and a first radio frequency front end unit electrically connected with the first radiator, the second antenna unit comprises a second radiator, a second radio frequency front end unit and at least one first isolation device, the first isolation device is electrically connected between the second radiator and the second radio frequency front end unit, a first gap is formed between the second radiator and the first radiator, and the first antenna unit and the first radiator are capacitively coupled through the first gap; one end of the second isolation device is electrically connected between the second radiator and the first isolation device or is electrically connected with the second radiator; the first proximity sensing device is electrically connected to the other end of the second isolation device. The application provides an antenna assembly and electronic equipment capable of improving communication quality and facilitating miniaturization of a whole machine.

Description

Antenna assembly and electronic equipment

Technical Field

The present application relates to the field of communications technologies, and in particular, to an antenna assembly and an electronic device.

Background

With the development of technology, electronic devices such as mobile phones with communication functions have become more and more popular and more powerful. An antenna assembly is typically included in an electronic device to enable communication functions of the electronic device. How to improve the communication quality of an electronic device and promote miniaturization of the electronic device is a technical problem to be solved.

Disclosure of Invention

The application provides an antenna assembly and electronic equipment capable of improving communication quality and facilitating miniaturization of a whole machine.

In a first aspect, embodiments of the present application provide an antenna assembly, including:

the antenna comprises a first antenna unit, a second antenna unit and a first radio frequency front-end unit, wherein the first antenna unit is used for receiving and transmitting electromagnetic wave signals of a first frequency band and comprises a first radiator and a first radio frequency front-end unit electrically connected with the first radiator;

the second antenna unit is used for receiving and transmitting electromagnetic wave signals of a second frequency band, the maximum value of the second frequency band is smaller than the minimum value of the first frequency band, the second antenna unit comprises a second radiator, a second radio frequency front end unit and at least one first isolation device, the first isolation device is electrically connected between the second radiator and the second radio frequency front end unit and used for isolating a first induction signal generated when a main body to be detected is close to the second radiator and conducting the electromagnetic wave signals of the second frequency band, a first gap is formed between the second radiator and the first radiator, and the first gap is used for capacitive coupling with the first radiator;

one end of the second isolation device is electrically connected between the second radiator and the first isolation device or electrically connected with the second radiator, and the second isolation device is used for isolating electromagnetic wave signals of the second frequency band and conducting the first induction signals; a kind of electronic device with high-pressure air-conditioning system

And the first proximity sensing device is electrically connected with the other end of the second isolation device and is used for sensing the magnitude of the first induction signal.

In a second aspect, an embodiment of the present application further provides an electronic device, including a controller and the antenna assembly, where the controller is configured to adjust power of at least one of the first antenna unit, the second antenna unit, and the third antenna unit according to the proximity state between the main body to be measured and the second radiator detected by the first proximity sensing device.

According to the antenna assembly provided by the embodiment of the application, the first gap is formed between the first radiator of the first antenna unit and the second radiator of the second antenna unit, wherein the first antenna unit is used for receiving and transmitting electromagnetic wave signals of a relatively high frequency band, and the second antenna unit is used for receiving and transmitting electromagnetic wave signals of a relatively low frequency band, so that on one hand, the first radiator and the second radiator can be capacitively coupled when the antenna assembly works to generate more modes, the bandwidth of the antenna assembly is improved, on the other hand, the first and second antenna units are high and low in frequency band, the isolation between the first and second antenna units is effectively improved, the antenna assembly is beneficial to radiating electromagnetic wave signals of a required frequency band, and as the radiators between the first and second antenna units can be mutually multiplexed, the antenna assembly can be realized to reduce the overall volume of the antenna assembly while the bandwidth is increased, and the overall miniaturization of electronic equipment is facilitated; further, the radiator on the multiplexing antenna assembly is an induction electrode which is close to a main body to be detected such as a human body, and the induction signal and the electromagnetic wave signal are isolated through the first isolation device and the second isolation device respectively, so that the communication performance of the antenna assembly and the effect of the main body to be detected are realized, the device utilization rate of the electronic equipment is further improved, and the whole volume of the electronic equipment is reduced.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of an electronic device according to an embodiment of the present application;

FIG. 2 is an exploded schematic view of the electronic device provided in FIG. 1;

fig. 3 is a schematic structural diagram of an antenna assembly according to an embodiment of the present disclosure;

fig. 4 is a schematic circuit diagram of the first antenna assembly provided in fig. 3;

fig. 5 is a graph of return loss for several resonant modes of operation of the first antenna element provided in fig. 4;

fig. 6 is a schematic structural diagram of a first fm filter circuit according to an embodiment of the present disclosure;

fig. 7 is a schematic structural diagram of a second first fm filter circuit according to an embodiment of the present application;

fig. 8 is a schematic structural diagram of a third first fm filter circuit according to an embodiment of the present disclosure;

fig. 9 is a schematic structural diagram of a fourth first fm filter circuit according to an embodiment of the present disclosure;

Fig. 10 is a schematic structural diagram of a fifth first fm filter circuit according to an embodiment of the present disclosure;

fig. 11 is a schematic structural diagram of a sixth first fm filter circuit according to an embodiment of the present application;

fig. 12 is a schematic structural diagram of a seventh first fm filter circuit according to an embodiment of the present disclosure;

fig. 13 is a schematic structural diagram of an eighth first fm filter circuit according to an embodiment of the present disclosure;

fig. 14 is a graph of return loss for several resonant modes of operation of the second antenna element provided in fig. 4;

fig. 15 is a schematic circuit diagram of a second antenna assembly provided in fig. 3;

fig. 16 is a schematic circuit diagram of a third antenna assembly provided in fig. 3;

fig. 17 is a schematic circuit diagram of a fourth antenna assembly provided in fig. 3;

fig. 18 is a schematic circuit diagram of a fifth antenna assembly provided in fig. 3;

fig. 19 is a graph of return loss for several resonant modes of operation of the third antenna element provided in fig. 4;

fig. 20 is an equivalent circuit diagram of the first antenna element provided in fig. 4;

fig. 21 is a schematic circuit diagram of a fourth antenna assembly provided in fig. 3;

fig. 22 is an equivalent circuit diagram of the second antenna element provided in fig. 4;

fig. 23 is a schematic circuit diagram of a fifth antenna assembly provided in fig. 3;

FIG. 24 is a schematic view of the structure of the middle frame of FIG. 2;

fig. 25 is a schematic structural diagram of the first antenna assembly provided in the embodiment of the present application disposed on the housing;

fig. 26 is a schematic structural diagram of a second antenna assembly provided in an embodiment of the present disclosure disposed on a housing;

fig. 27 is a schematic structural diagram of a third antenna assembly provided in an embodiment of the present application disposed on a housing.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all, of the embodiments of the present application. The embodiments listed in this application may be appropriately combined with each other.

Referring to fig. 1, fig. 1 is a schematic structural diagram of an electronic device 1000 according to an embodiment of the present disclosure. The electronic device 1000 may be a device capable of receiving and transmitting electromagnetic wave signals, such as a telephone, a television, a tablet computer, a mobile phone, a camera, a personal computer, a notebook computer, a vehicle-mounted device, an earphone, a watch, a wearable device, a base station, a vehicle-mounted radar, a customer premises equipment (Customer Premise Equipment, CPE), or the like. Taking the electronic device 1000 as a mobile phone for example, for convenience of description, the width direction of the electronic device 1000 is defined as the X direction, the length direction of the electronic device 1000 is defined as the Y direction, and the thickness direction of the electronic device 1000 is defined as the Z direction, which are defined with reference to the electronic device 1000 being at the first viewing angle. The direction indicated by the arrow is forward.

Referring to fig. 2, an electronic device 1000 includes an antenna assembly 100. The antenna assembly 100 is used for receiving and transmitting radio frequency signals to realize the communication function of the electronic device 1000. At least part of the components of the antenna assembly 100 are disposed on the motherboard 200 of the electronic device 1000. It can be appreciated that the electronic device 1000 further includes a device capable of implementing the basic functions of the mobile phone, such as the display 300, the battery 400, the housing 500, the camera, the microphone, the receiver, the speaker, the face recognition module, the fingerprint recognition module, and the like, which will not be described in detail in this embodiment.

Referring to fig. 3, the antenna assembly 100 includes a first antenna unit 10, a second antenna unit 20, and a reference ground 40. The first antenna unit 10 is configured to transmit and receive electromagnetic wave signals in a first frequency band. The second antenna unit 20 is used for receiving and transmitting electromagnetic wave signals in a second frequency band. Wherein the first frequency band and the second frequency band are different frequency bands. Specifically, the minimum value of the first frequency band is greater than the maximum value of the second frequency band. For example, the first Band is a Middle High Band (MHB) and an Ultra High Band (UHB), and the second Band is a Low Band (LB). Wherein the low frequency band is lower than 1000MHz, the medium and high frequency bands are 1000MHz-3000MHz, and the ultra-high frequency band is 3000MHz-10000Mhz. In other words, the first antenna unit 10 and the second antenna unit 20 are antenna units for receiving and transmitting different frequency bands, so that the bandwidth of the antenna assembly 100 is larger.

Referring to fig. 4, the first antenna unit 10 includes at least a first radiator 11 and a first rf front-end unit 61. The first radiator 11 is electrically connected to the first rf front-end unit 61. The first rf front-end unit 61 at least includes a first signal source 12 and a first fm filter circuit M1.

The shape of the first radiator 11 is not particularly limited in this application. The shape of the first radiator 11 includes, but is not limited to, a bar, a sheet, a rod, a wire, a coating, a film, and the like. In this embodiment, the first radiator 11 is elongated.

The first radiator 11 includes a first ground terminal G1 and a first coupling terminal H1 disposed opposite to each other, and a first feeding point a disposed between the first ground terminal G1 and the first coupling terminal H1.

The first ground terminal G1 is electrically connected to the reference ground 40. The reference ground 40 includes a first reference ground GND1. The first ground terminal G1 is electrically connected to the first reference ground GND1.

The first fm filter circuit M1 is disposed between the first feeding point a and the first signal source 12. Specifically, the first signal source 12 is electrically connected to an input end of the first fm filter circuit M1, and an output end of the first fm filter circuit M1 is electrically connected to the first feeding point a of the first radiator 11. The first signal source 12 is configured to generate an excitation signal (also referred to as a radio frequency signal), and the first fm filter circuit M1 is configured to filter clutter of the excitation signal transmitted by the first signal source 12 to obtain excitation signals in the mid-high frequency and ultra-high frequency bands, and transmit the excitation signals in the mid-high frequency and ultra-high frequency bands to the first radiator 11, so that the first radiator 11 transmits and receives electromagnetic wave signals in the first frequency band.

Referring to fig. 4, the second antenna unit 20 includes a second radiator 21, a second rf front end unit 62, and at least one first isolation device 71. The antenna assembly further comprises at least one second isolation device 72. The second rf front-end unit 62 includes the second signal source 22 and the second fm filter circuit M2. The reference ground to which the first rf front-end unit 61 is electrically connected and the reference ground to which the second rf front-end unit 62 is electrically connected may be the same reference ground.

The first isolation device 71 is arranged between the second radiator 21 and the second radio frequency front end unit 62. The first isolation device 71 is used for isolating a first induction signal generated when the main body to be tested approaches to the second radiator 21 and conducting electromagnetic wave signals of the second frequency band.

One end of the second isolation device 72 is electrically connected between the second radiator 21 and the first isolation device 71 or the second radiator 21. The second isolation device 72 is used for isolating electromagnetic wave signals in the second frequency band and conducting the first induction signals.

The first proximity sensing device 81 is electrically connected to the other end of the second isolation device 72. The first proximity sensing device 81 is used for sensing the magnitude of the first sensing signal. In this embodiment, the main body to be measured is a human body, and because the surface of the main body to be measured has charges, when the main body to be measured approaches to the second radiator 21, the charges on the surface of the second radiator 21 change, which is represented by a first induction signal change.

Specifically, the first isolation device 71 includes an isolation capacitance, and the second isolation device 72 includes an isolation inductance. When the main body to be measured approaches the second radiator 21, the first induction signal generated by the second radiator 21 is a direct current signal. The electromagnetic wave signal is an alternating current signal. By providing the first isolation device 71 between the second radiator 21 and the second rf front-end unit 62, the first inductive signal does not flow to the second rf front-end unit 62 through the second radiator 21, so as to affect the signal transmission and reception of the second antenna unit 20. The first isolation device 71 makes the second radiator 21 in a "floating" state with respect to the dc signal to sense the capacitance change caused by the approach of the human body. By providing the second isolation device 72 between the first proximity sensing device 81 and the second radiator 21 so that the electromagnetic wave signal does not flow to the first proximity sensing device 81 through the second radiator 21, the sensing efficiency of the first proximity sensing device 81 for the first sensing signal is improved. The specific structure of the first proximity sensing device 81 is not limited in this application, and the first proximity sensing device 81 includes, but is not limited to, a sensor for sensing a capacitance change or an inductance change.

The shape of the second radiator 21 is not particularly limited in this application. The shape of the second radiator 21 includes, but is not limited to, a bar, a sheet, a rod, a coating, a film, and the like. In this embodiment, the second radiator 21 is elongated.

Referring to fig. 4, the second radiator 21 includes a second coupling end H2 and a third coupling end H3 disposed opposite to each other, and a second feeding point C disposed between the second coupling end H2 and the third coupling end H3.

The second coupling end H2 and the first coupling end H1 are disposed at intervals to form a first gap 101. In other words, a first slit 101 is formed between the second radiator 21 and the first radiator 11. The first radiator 11 and the second radiator 21 are capacitively coupled through the first slit 101. The "capacitive coupling" means that an electric field is generated between the first radiator 11 and the second radiator 21, a signal of the first radiator 11 can be transmitted to the second radiator 21 through the electric field, and a signal of the second radiator 21 can be transmitted to the first radiator 11 through the electric field, so that the first radiator 11 and the second radiator 21 can be electrically connected even in a disconnected state.

The size of the first slit 101 is not specifically limited in this application, and in this embodiment, the size of the first slit 101 is less than or equal to 2mm, but is not limited to this size, so that the capacitive coupling between the first radiator 11 and the second radiator 21 is formed.

The specific formation modes of the first radiator 11 and the second radiator 21 are not particularly limited in this application. The first radiator 11 is a flexible circuit board (Flexible Printed Circuit, FPC) antenna radiator or a laser direct structuring (Laser Direct Structuring, LDS) antenna radiator or a printed direct structuring (Print Direct Structuring, PDS) antenna radiator or a metal stub or the like; the second radiator 21 is an FPC antenna radiator, an LDS antenna radiator, a PDS antenna radiator, a metal branch, or the like.

Specifically, the first radiator 11 and the second radiator 21 are made of conductive materials, and specific materials include, but are not limited to, metals, transparent conductive oxides (such as indium tin oxide ITO), carbon nanotubes, graphene, and the like. In this embodiment, the material of the first radiator 11 is a metal material, for example, silver, copper, etc.

The second fm filter circuit M2 is disposed between the second feeding point C and the second signal source 22. Specifically, the second signal source 22 is electrically connected to the input end of the second fm filter circuit M2, and the output end of the second fm filter circuit M2 is electrically connected to the second radiator 21. The second signal source 22 is configured to generate an excitation signal, and the second fm filter circuit M2 is configured to filter clutter of the excitation signal transmitted by the second signal source 22 to obtain a low-frequency excitation signal, and transmit the low-frequency excitation signal to the second radiator 21, so that the second radiator 21 receives and transmits an electromagnetic wave signal in the second frequency band.

When the antenna assembly 100 is applied to the electronic device 1000, the first signal source 12, the second signal source 22, the first fm filter circuit M1, and the second fm filter circuit M2 can be disposed on the motherboard 200 of the electronic device 1000. In the present embodiment, the first fm filter circuit M1 and the second fm filter circuit M2 may be configured to transmit and receive electromagnetic wave signals in different frequency bands from the first antenna unit 10 and the second antenna unit 20, so as to improve the isolation between the first antenna unit 10 and the second antenna unit 20. In other words, the first fm filter circuit M1 and the second fm filter circuit M2 can isolate the electromagnetic wave signals transmitted and received by the first antenna unit 10 and the electromagnetic wave signals transmitted and received by the second antenna unit 20 from interfering with each other.

The first antenna element 10 is configured to generate a plurality of first resonant modes. Furthermore, at least one first resonant mode is created by the capacitive coupling of the first radiator 11 with the second radiator 21.

Referring to fig. 5, the plurality of first resonant modes includes at least a first sub-resonant mode a, a second sub-resonant mode b, a third sub-resonant mode c and a fourth sub-resonant mode d. It should be noted that the plurality of first resonant modes further include modes other than the resonant modes listed above, and the four resonant modes are only relatively efficient modes.

Wherein the second sub-resonance mode b and the third sub-resonance mode c are both generated by coupling the first radiator 11 and the second radiator 21. The frequency band of the first sub-resonance mode a, the frequency band of the second sub-resonance mode b, the frequency band of the third sub-resonance mode c and the frequency band of the fourth sub-resonance mode d correspond to the first sub-frequency band, the second sub-frequency band, the third sub-frequency band and the fourth sub-frequency band, respectively. In one embodiment, the first sub-band is between 1900 and 2000 MHz; the second sub-frequency band is 2600-2700 MHz; the third sub-band is 3800-3900 MHz; the fourth sub-band is between 4700 and 4800 MHz. In other words, the electromagnetic wave signals of the plurality of first resonance modes are located in the middle-high frequency band (1000 MHz-3000 MHz) and the ultra-high frequency band (3000 MHz-10000 MHz). By adjusting the resonance frequency point of the resonance mode, the first antenna unit 10 can fully cover the medium-high frequency and the ultrahigh frequency, and obtain higher efficiency in a required frequency band.

As can be seen from the above, when the first antenna element 10 does not have a coupling antenna element, the first antenna element 10 generates a first sub-resonance mode a and a fourth sub-resonance mode d. When the first antenna unit 10 is coupled to the second antenna unit 20, the first antenna unit 10 generates not only the first sub-resonant mode a and the fourth sub-resonant mode d, but also the second sub-resonant mode b and the third sub-resonant mode c, which can be known that the bandwidth of the antenna assembly 100 increases.

Since the first radiator 11 and the second radiator 21 are disposed at intervals and coupled to each other, that is, the first radiator 11 and the second radiator 21 are common in caliber. When the antenna assembly 100 is in operation, a first excitation signal generated by the first signal source 12 may be coupled to the second radiator 21 via the first radiator 11. In other words, the first antenna unit 10 can operate using not only the first radiator 11 but also the second radiator 21 in the second antenna unit 20 to transmit and receive electromagnetic wave signals, so that the first antenna unit 10 can operate in a wide frequency band. Similarly, the second radiator 21 and the first radiator 11 are disposed at intervals and are coupled to each other, and when the antenna assembly 100 is operated, the second excitation signal generated by the second signal source 22 can be coupled to the first radiator 11 via the second radiator 21, in other words, when the second antenna unit 20 is operated, not only the second radiator 21 but also the first radiator 11 in the first antenna unit 10 can be used to transmit and receive electromagnetic wave signals, so that the second antenna unit 20 can operate in a wider frequency band. Since the second antenna unit 20 can use the second radiator 21 and the first radiator 11 when working, and the first antenna unit 10 can use the first radiator 11 and the second radiator 21 when working, the radiation performance of the antenna assembly 100 is improved, the multiplexing of the radiators is realized, the multiplexing of the space is realized, the size of the antenna assembly 100 is reduced, and the whole volume of the electronic device 1000 is reduced.

According to the antenna assembly 100 provided by the embodiment of the invention, the first gap 101 is formed between the first radiator 11 and the second antenna unit 20 of the first antenna unit 10 and the second radiator 21, wherein the first antenna unit 10 is used for receiving and transmitting electromagnetic wave signals in a relatively high frequency band, and the second antenna unit 20 is used for receiving and transmitting electromagnetic wave signals in a relatively low frequency band, so that on one hand, the first radiator 11 and the second radiator 21 can be capacitively coupled to generate more modes when the antenna assembly 100 works, the bandwidth of the antenna assembly 100 is improved, on the other hand, the first frequency band of the first antenna unit 10 and the second antenna unit 20 is higher than the second frequency band of the first antenna unit 10, the isolation between the first antenna unit 10 and the second antenna unit 20 is effectively improved, the antenna assembly 100 can radiate electromagnetic wave signals in a required frequency band, and mutual multiplexing is realized by the radiators between the first antenna unit 10 and the second antenna unit 20, so that the antenna assembly 100 can also reduce the whole volume of the antenna assembly 100 while increasing the bandwidth, and is beneficial to the whole miniaturization of the electronic equipment 1000; further, the radiator on the multiplexing antenna assembly 100 is an induction electrode for detecting the approach of the human body waiting to be measured, and the first isolation device 71 and the second isolation device 72 isolate the induction signal and the electromagnetic wave signal respectively, so that the communication performance of the antenna assembly 100 and the effect of the induction main body to be measured are realized, the device utilization rate of the electronic equipment 1000 is further improved, and the whole volume of the electronic equipment 1000 is reduced.

In the related art, more antenna units are required or the length of the radiator is required to be increased to support the first to fourth sub-resonance modes, which results in a larger size of the antenna assembly. In the antenna assembly 100 of the embodiment of the present application, there is no need to provide additional antenna units to support the second sub-resonant mode b and the third sub-resonant mode c, so that the volume of the antenna assembly 100 is smaller. Setting an additional antenna to support the second sub-resonant mode b and setting an additional antenna to support the third sub-resonant mode c may also result in higher costs for the antenna assembly 100; the difficulty in stacking the antenna assembly 100 with other devices increases when the antenna assembly 100 is used in the electronic device 1000. In the embodiment of the present application, the antenna assembly 100 does not need to additionally provide an antenna to support the second sub-resonant mode b and the third sub-resonant mode c, so that the cost of the antenna assembly 100 is low; the antenna assembly 100 is less difficult to stack when applied to the electronic device 1000. In addition, the provision of an additional antenna to support the second sub-resonant mode b and the provision of an additional antenna to support the third sub-resonant mode c may also result in increased radio frequency link insertion loss of the antenna assembly 100. The antenna assembly 100 of the present application may reduce radio frequency link insertion loss.

Embodiments in which the first antenna unit 10 and the second antenna unit 20 form a transceiver for electromagnetic waves of different frequency bands include, but are not limited to, the following embodiments.

Specifically, the first signal source 12 and the second signal source 22 may be the same signal source or may be different signal sources.

In one possible embodiment, the first signal source 12 and the second signal source 22 may be the same signal source. The same signal source transmits excitation signals to the first frequency modulation filter circuit M1 and the second frequency modulation filter circuit M2 respectively, and the first frequency modulation filter circuit M1 is a filter circuit for blocking high and ultra-high frequencies in low frequency pass. The second frequency modulation filter circuit M2 is a filter circuit for blocking medium-high ultrahigh frequency pass low frequency. The middle-high ultrahigh frequency part of the excitation signal flows to the first radiator 11 through the first fm filter circuit M1, so that the first radiator 11 transmits and receives electromagnetic wave signals of the first frequency band. The low-frequency part of the excitation signal flows to the second radiator 21 through the second fm filter circuit M2, so that the second radiator 21 transmits and receives electromagnetic wave signals of the second frequency band.

In another possible embodiment, the first signal source 12 and the second signal source 22 are different signal sources. The first signal source 12 and the second signal source 22 may be integrated into one chip or separately packaged chips. The first signal source 12 is configured to generate a first excitation signal, where the first excitation signal is loaded on the first radiator 11 through the first fm filter circuit M1, so that the first radiator 11 receives and transmits electromagnetic wave signals in the first frequency band. The second signal source 22 is configured to generate a second excitation signal, where the second excitation signal is loaded on the second radiator 21 via the second fm filter circuit M2, so that the second radiator 21 receives and transmits electromagnetic wave signals in the second frequency band.

It is understood that the first fm filter circuit M1 includes, but is not limited to, a capacitor, an inductor, a resistor, etc. disposed in series and/or parallel, and the first fm filter circuit M1 may include a plurality of branches formed by the capacitor, the inductor, the resistor, etc. connected in series and/or parallel, and a switch for controlling the on/off of the plurality of branches. The on-off of different switches can be controlled to adjust the frequency selection parameters (including resistance value, inductance value and capacitance value) of the first frequency modulation filter circuit M1, so as to adjust the filtering range of the first frequency modulation filter circuit M1, thereby enabling the first antenna unit 10 to transmit and receive electromagnetic wave signals of the first frequency band. Similarly, the second fm filter circuit M2 includes, but is not limited to, a capacitor, an inductor, a resistor, etc. disposed in series and/or parallel, and the second fm filter circuit M2 may include a plurality of branches formed by the capacitor, the inductor, the resistor, etc. connected in series and/or parallel, and a switch for controlling the on/off of the plurality of branches. The on-off of the different switches can be controlled to adjust the frequency selection parameters (including resistance value, inductance value and capacitance value) of the second frequency modulation filter circuit M2, so as to adjust the filtering range of the second frequency modulation filter circuit M2, thereby enabling the second antenna unit 20 to transmit and receive electromagnetic wave signals of the second frequency band. The first fm filter circuit M1 and the second fm filter circuit M2 may also be referred to as matching circuits.

Referring to fig. 6 to fig. 13 together, fig. 6 to fig. 13 are schematic diagrams of a first fm filter circuit M1 according to various embodiments. The first fm filter circuit M1 includes one or more of the following circuits.

Referring to fig. 6, the first fm filter circuit M1 includes a band-pass circuit formed by connecting an inductor L0 and a capacitor C0 in series.

Referring to fig. 7, the first fm filter circuit M1 includes a band-stop circuit formed by connecting an inductor L0 and a capacitor C0 in parallel.

Referring to fig. 8, the first fm filter circuit M1 includes an inductor L0, a first capacitor C1, and a second capacitor C2. The inductor L0 is connected in parallel with the first capacitor C1, and the second capacitor C2 is electrically connected to a node where the inductor L0 is electrically connected to the first capacitor C1.

Referring to fig. 9, the first fm filter circuit M1 includes a capacitor C0, a first inductor L1, and a second inductor L2. The capacitor C0 is connected in parallel with the first inductor L1, and the second inductor L2 is electrically connected to a node where the capacitor C0 is electrically connected to the first inductor L1.

Referring to fig. 10, the first fm filter circuit M1 includes an inductor L0, a first capacitor C1, and a second capacitor C2. The inductor L0 is connected in series with the first capacitor C1, and one end of the second capacitor C2 is electrically connected to the first end of the inductor L0, which is not connected to the first capacitor C1, and the other end of the second capacitor C2 is electrically connected to the first end of the first capacitor C1, which is not connected to the inductor L0.

Referring to fig. 11, the first fm filter circuit M1 includes a capacitor C0, a first inductor L1, and a second inductor L2. The capacitor C0 is connected in series with the first inductor L1, one end of the second inductor L2 is electrically connected with one end of the capacitor C0, which is not connected with the first inductor L1, and the other end of the second inductor L2 is electrically connected with one end of the first inductor L1, which is not connected with the capacitor C0.

Referring to fig. 12, the first fm filter circuit M1 includes a first capacitor C1, a second capacitor C2, a first inductor L1, and a second inductor L2. The first capacitor C1 is connected with the first inductor L1 in parallel, the second capacitor C2 is connected with the second inductor L2 in parallel, and one end of the whole formed by connecting the second capacitor C2 with the second inductor L2 in parallel is electrically connected with one end of the whole formed by connecting the first capacitor C1 with the first inductor L1 in parallel.

Referring to fig. 13, the first fm filter circuit M1 includes a first capacitor C1, a second capacitor C2, a first inductor L1, and a second inductor L2, wherein the first capacitor C1 and the first inductor L1 are connected in series to form a first unit 111, the second capacitor C2 and the second inductor L2 are connected in series to form a second unit 112, and the first unit 111 and the second unit 112 are connected in parallel.

Referring to fig. 14, the second antenna unit 20 generates a second resonant mode during operation. The frequency band of the second resonant mode is below 1000MHz, e.g., 500-1000 MHz. By adjusting the resonance frequency point of the resonance mode, the second antenna unit 20 can fully cover the low frequency and obtain higher efficiency in the required frequency band. Thus, the second antenna unit 20 can transmit and receive electromagnetic wave signals in low frequency bands, for example, electromagnetic wave signals in all low frequency bands of 4G (also called Long Term Evolution, LTE) and 5G (also called New Radio, NR). When the second antenna unit 20 and the first antenna unit 10 work simultaneously, electromagnetic wave signals of all low frequency bands, medium frequency bands and ultra-high frequency bands of 4G and 5G can be covered simultaneously, including LTE-1/2/3/4/7/32/40/41, NR-1/3/7/40/41/77/78/79, wi-Fi 2.4G, wi-Fi 5G, GPS-L1, GPS-L5 and the like, so that ultra-wideband carrier aggregation (Carrier Aggregation, CA) and double connection (LTE NR Double Connect, ENDC) combination of the 4G wireless access network and the 5G-NR are realized.

Referring to fig. 15, the first antenna unit 10 further includes a third isolation device 73. The third isolation device 73 is disposed between the first radiator 11 and the first rf front-end unit 61 and between the first ground terminal G1 and the first reference ground GND1, and is configured to isolate a second induction signal generated when the subject to be tested approaches the first radiator 11 and an electromagnetic wave signal for conducting the first frequency band. Specifically, the third isolation device 73 includes an isolation capacitance. The third isolation device 73 is used to put the first radiator 11 in a "floating" state with respect to the direct current signal.

In a first possible embodiment, referring to fig. 15, the second sensing signal is used to generate a sub-sensing signal by the coupling action of the first radiator 11 and the second radiator 21, and the first proximity sensing device 81 is further used to sense the magnitude of the sub-sensing signal.

In this embodiment, the first radiator 11 and the second radiator 21 are both used as sensing electrodes for sensing the approach of the body to be measured, and the approach sensing path of the first radiator 11 is from the first radiator 11, the second radiator 21 to the first proximity sensor 81. In other words, when the subject to be measured approaches the first radiator 11, the first radiator 11 generates the second sensing signal, and the second radiator 21 generates the sub-sensing signal through the coupling effect, so that the first proximity sensing device 81 can sense the subject to be measured at the first radiator 11. The coupling effect between the first radiator 11 and the second radiator 21 and the first proximity sensing device 81 are fully utilized without using two proximity sensing devices 81, so that the first radiator 11 and the second radiator 21 can be reused in proximity detection, the utilization rate of devices is increased, the number of devices is reduced, and integration and miniaturization of the electronic equipment 1000 are further promoted.

Further, referring to fig. 16, the antenna assembly 100 further includes a fourth isolation device 74. One end of the fourth isolation device 74 is electrically connected between the first radiator 11 and the third isolation device 73 or electrically connected to the first radiator 11, for isolating electromagnetic wave signals of the first frequency band and conducting the second induction signals. Specifically, the fourth isolation device 74 includes an isolation inductance.

In a second possible embodiment, referring to fig. 16, the antenna assembly 100 further includes a second proximity sensing device 82, and the second proximity sensing device 82 is electrically connected to the other end of the fourth isolation device 74, for sensing the magnitude of the second sensing signal. Specifically, the first radiator 11 and the second radiator 21 are both sensing electrodes for sensing the approach of the main body to be measured, and the approach sensing path of the first radiator 11 and the approach sensing path of the second radiator 21 are mutually independent, so that the approach of the main body to be measured to the first radiator 11 or the second radiator 21 can be accurately detected, and the approach behavior can be responded timely. Specifically, when the main body to be measured is close to the first radiator 11, the second induction signal generated by the first radiator 11 is a direct current signal. The electromagnetic wave signal is an alternating current signal. By providing the third isolation device 73 between the first radiator 11 and the first rf front-end unit 61, the second inductive signal does not flow to the first rf front-end unit 61 via the first radiator 11, so as to affect the signal transmission and reception of the first antenna unit 10. By providing the fourth isolation device 74 between the second proximity sensing device 82 and the first radiator 11 so that electromagnetic wave signals do not flow to the second proximity sensing device 82 through the first radiator 11, the sensing efficiency of the second proximity sensing device 82 for the second sensing signal is improved.

In other embodiments, the coupling of the second radiator 21 to the first radiator 11 may be utilized to transmit the inductive signal of the second radiator 21 through the first radiator 11 to the second proximity sensing device 82.

In a third possible embodiment, referring to fig. 17, the other end of the fourth isolation device 74 is electrically connected to the first proximity sensing device 81. The first radiator 11 and the second radiator 21 generate a coupling induction signal when capacitively coupled. The first proximity sensing device 81 is further configured to sense a variation of the coupling sensing signal when the subject to be measured approaches the first radiator 11 and/or the second radiator 21.

Specifically, a constant electric field is generated when the first radiator 11 and the second radiator 12 are coupled, which is shown as generating a stable coupling induction signal. When a human body approaches the constant electric field, the constant electric field changes, which is expressed as a change of the coupling induction signal, and the approach of the human body is detected according to the change amount of the coupling induction signal.

In the present embodiment, the first radiator 11 and the second radiator 12 are simultaneously used as sensing electrodes, and accurate detection can be performed when a human body approaches the region corresponding to the first radiator 11, the region corresponding to the second radiator 12, and the region corresponding to the first slit 101. The coupling effect between the first radiator 11 and the second radiator 21 and the first proximity sensing device 81 are fully utilized without using two proximity sensing devices 81, so that the first radiator 11 and the second radiator 21 can be reused in proximity detection, the utilization rate of devices is increased, the number of devices is reduced, and integration and miniaturization of the electronic equipment 1000 are further promoted.

The specific structure of the second proximity sensing device 82 is not limited in this application, and the second proximity sensing device 82 includes, but is not limited to, a sensor for sensing a capacitance change or an inductance change.

Further, the antenna assembly 100 further comprises a third antenna element 30. The third antenna unit 30 is configured to transmit and receive electromagnetic wave signals in a third frequency band. The minimum value of the third frequency band is greater than the maximum value of the second frequency band. Optionally, the third frequency band is equal to the first frequency band; or the third frequency band is partially overlapped with the first frequency band, and the other part is not overlapped; or the third frequency band is completely misaligned with the first frequency band, and the minimum value of the third frequency band is larger than the maximum value of the first frequency band; or the first frequency band and the third frequency band are not overlapped completely, and the minimum value of the first frequency band is larger than the maximum value of the third frequency band. In this embodiment, the range of the first frequency band and the third frequency band is 1000-10000 MHz.

Referring to fig. 18, the third antenna unit 30 includes a third radiator 31, a third rf front end unit 63, and a fifth isolation device 75. The third rf front-end unit 63 includes the third signal source 32 and the third fm filter circuit M3. The reference ground 40 of the first rf front-end unit 61, the reference ground electrically connected to the second rf front-end unit 62, and the reference ground electrically connected to the third rf front-end unit 63 are the same reference ground.

The antenna assembly 100 also includes a sixth isolation device 76 and a third proximity sensing device 83. The third isolation device 73 is disposed between the third radiator 31 and the third rf front-end unit 63 and between the second ground terminal G2 and the second reference ground GND2, and is configured to isolate a third induction signal generated when the subject to be tested approaches the third radiator 31 and an electromagnetic wave signal for conducting the third frequency band. One end of the sixth isolation device 76 is electrically connected between the third radiator 31 and the third isolation device 73, and is used for isolating the electromagnetic wave signal of the third frequency band and conducting the third induction signal. The third proximity sensing device 83 is electrically connected to the other end of the sixth isolation device 76 for sensing the magnitude of the third sensing signal.

Specifically, the fifth isolation device 75 includes an isolation capacitance, and the sixth isolation device 76 includes an isolation inductance. When the main body to be measured approaches the third radiator 31, the third induction signal generated by the third radiator 31 is a dc signal. The electromagnetic wave signal is an alternating current signal. By disposing the fifth isolation device 75 between the third radiator 31 and the third rf front-end unit 63, the third inductive signal does not flow to the third rf front-end unit 63 through the third radiator 31, so as to affect the signal transmission and reception of the third antenna unit 30. By providing the sixth isolation device 76 between the third proximity sensing device 83 and the third radiator 31 so that electromagnetic wave signals do not flow to the third proximity sensing device 83 via the third radiator 31, the sensing efficiency of the third proximity sensing device 83 for the third sensing signal is improved.

The specific structure of the third proximity sensing device 83 is not limited in this application, and the third proximity sensing device 83 includes, but is not limited to, a sensor for sensing a capacitance change or an inductance change.

Thus, any one or more of the first radiator 11, the second radiator 21, and the third radiator 31 can be used as an induction electrode for sensing the proximity of a subject (e.g., a human body) to be measured.

A second slit 102 is formed between the third radiator 31 and the second radiator 21. The third radiator 31 is capacitively coupled to the second radiator 21 through a second slit 102. Specifically, the third radiator 31 includes a fourth coupling end H4 and a second ground end G2 disposed at both ends, and a third feeding point E disposed between the fourth coupling end H4 and the second ground end G2. A second gap 102 is formed between the fourth coupling end H4 and the third coupling end H3. One end of the third fm filter circuit M3 is electrically connected to the third feeding point E, and the other end of the third fm filter circuit M3 is electrically connected to the third signal source 32. Optionally, when the antenna assembly 100 is applied to the electronic device 1000, the third signal source 32 and the third fm filter circuit M3 are disposed on the motherboard 200. Optionally, the third signal source 32 is the same signal source as the first signal source 12 and the second signal source 22, or the third signal source 32 is a different signal source from the first signal source 12 and the second signal source 22. The third fm filter circuit M3 is configured to filter clutter of the radio frequency signal transmitted by the third signal source 32, so that the third antenna unit 30 receives and transmits electromagnetic wave signals of a third frequency band. The reference ground 40 includes a second reference ground GND2. The second ground terminal G2 is electrically connected to the second reference ground GND2.

It can be appreciated that the third radiator 31 serves as an induction electrode for inducing the approach of the human body, and a specific induction path thereof may be independent from the induction path of the second radiator 21, or may be transmitted to the first proximity sensing device 81 after coupling with the second radiator 21, or may generate a coupling induction signal when forming capacitive coupling with the second radiator 21, and may transmit the coupling induction signal to the first proximity sensing device 81. The specific embodiment may refer to the embodiment in which the first radiator 11 is used as an induction electrode, and will not be described herein.

The third antenna element 30 is configured to generate a plurality of third resonant modes. At least one third resonant mode is created by the capacitive coupling of the second radiator 21 with the third radiator 31.

Referring to fig. 19, the plurality of third resonant modes at least includes a fifth sub-resonant mode e, a sixth sub-resonant mode f, a seventh sub-resonant mode g and an eighth sub-resonant mode h. The plurality of third resonant modes include modes other than the resonant modes listed above, and the four resonant modes are only relatively efficient modes.

The electromagnetic waves of the sixth sub-resonance mode f and the seventh sub-resonance mode g are generated by coupling the third radiator 31 and the second radiator 21. The frequency band of the fifth sub-resonance mode e, the frequency band of the sixth sub-resonance mode f, the frequency band of the seventh sub-resonance mode g and the frequency band of the eighth sub-resonance mode h correspond to the fifth sub-frequency band, the sixth sub-frequency band, the seventh sub-frequency band and the eighth sub-frequency band, respectively. In one embodiment, the fifth sub-band is between 1900 and 2000 MHz; the sixth frequency sub-band is 2600-2700 MHz; the seventh sub-band is 3800-3900 MHz; the eighth frequency sub-band is between 4700 and 4800 MHz. In other words, the plurality of third resonance modes are located in the middle-high frequency band (1000 MHz-3000 MHz) and the ultra-high frequency band (3000 MHz-10000 MHz). By adjusting the resonance frequency point of the resonance mode, the third antenna unit 30 can fully cover the medium-high frequency and the ultrahigh frequency, and obtain higher efficiency in the required frequency band.

Alternatively, the structure of the third antenna element 30 is the same as that of the first antenna element 10. The capacitive coupling between the third antenna element 30 and the second antenna element 20 is the same as the capacitive coupling between the first antenna element 10 and the second antenna element 20. As such, when the antenna assembly 100 is in operation, the third excitation signal generated by the third signal source 32 can be coupled to the second radiator 21 via the third radiator 31. In other words, when the third antenna unit 30 works, not only the third radiator 31 but also the second radiator 21 in the second antenna unit 20 can be utilized to transmit and receive electromagnetic wave signals, so that the working bandwidth of the third antenna unit 30 is increased on the basis that no additional radiator is added.

Because the first antenna unit 10, the second antenna unit 20 and the third antenna unit 30 are respectively transmitting and receiving medium-high ultrahigh frequency, low frequency and medium-high ultrahigh frequency, the first antenna unit 10 and the second antenna unit 20 and the third antenna unit 30 are isolated by frequency bands so as to avoid signal interference between each other, and the first antenna unit 10 and the third antenna unit 30 are isolated by physical intervals so as to avoid signal interference between each other, so that the antenna assembly 100 can be controlled to transmit and receive electromagnetic wave signals of a required frequency band.

In addition, the first antenna unit 10 and the third antenna unit 30 may be disposed at different orientations or positions on the electronic device 1000, so as to switch under different scenarios, for example, the first antenna unit 10 and the third antenna unit 30 may be switched when the electronic device 1000 switches between a landscape screen and a portrait screen, or the first antenna unit 10 may be switched to the third antenna unit 30 when it is blocked, and the third antenna unit 30 may be switched to the first antenna unit 10 when it is blocked, so as to have better transmission and reception of the medium-high ultrahigh frequency electromagnetic waves under different scenarios.

In this embodiment, the tuning mode of the antenna assembly 100 with the first antenna unit 10, the second antenna unit 20, and the third antenna unit 30 for realizing electromagnetic wave signal coverage of all low frequency bands, medium-high frequency bands, and ultra-high frequency bands of 4G and 5G is exemplified.

Referring to fig. 20, the second radiator 21 includes a first coupling point C'. The first coupling point C' is located between the second coupling end H2 and the third coupling end H3. The portion from the first coupling point C' to the end of the second radiator 21 is for coupling with other adjacent radiators.

Referring to fig. 20, the first isolation device 71 includes a first isolation capacitor C3. The first isolation capacitor C3 is electrically connected between the first coupling point C' and the reference ground 40. The first isolation capacitor C3 is used for isolating the first induction signal from entering the reference ground 40 through the first coupling point C', so as to affect the receiving and transmitting of the electromagnetic wave signal.

When the first coupling point C 'is disposed near the second coupling end H2, the second radiator 21 between the first coupling point C' and the second coupling end H2 is coupled with the first radiator 11. Further, a first coupling segment R1 is formed between the first coupling point C' and the second coupling end H2. The first coupling segment R1 is for capacitive coupling with the first radiator 11. The length of the first coupling segment R1 is 1/4 lambda 1. Wherein λ1 is the wavelength of the electromagnetic wave signal corresponding to the first frequency band.

When the first coupling point C 'is disposed near the third coupling end H3, the second radiator 21 and the third radiator 31 between the first coupling point C' and the third coupling end H3 are coupled. The second coupling segment R2 is formed between the first coupling point C' and the third coupling end H3. The second coupling segment R2 is for capacitive coupling with the third radiator 31. The length of the second coupling segment R2 is 1/4 lambda 2. Wherein λ2 is the wavelength of the electromagnetic wave signal corresponding to the third frequency band.

In this embodiment, the first coupling point C 'is taken as an example close to the second coupling end H2 for illustration, and of course, the following arrangement of the first coupling point C' is also applicable to the case close to the third coupling end H3.

The first coupling point C' is used for grounding, so that the first excitation signal emitted by the first signal source 12 is filtered by the first fm filter circuit M1 and then transmitted from the first feed point a to the first radiator 11, and the excitation signal has different modes of action on the first radiator 11, for example, the first excitation signal acts from the first feed point a toward the first ground terminal G1, and enters the reference ground electrode 40 at the first ground terminal G1 to form an antenna loop; the first excitation signal acts from the first feeding point a toward the first coupling end H1, is coupled to the second coupling end H2 and the first coupling point C 'through the first slot 101, and enters the reference ground 40 from the first coupling point C', forming another coupled antenna loop.

Specifically, the first antenna element 10 generates the first sub-resonance mode a when operating in the fundamental modes of the first ground G1 to the first coupling H1. Specifically, when the first excitation signal generated by the first signal source 12 acts between the first ground terminal G1 and the second coupling terminal H2, a first sub-resonance mode a is generated, and the resonance frequency point corresponding to the first sub-resonance mode a has higher efficiency, so that the communication quality of the electronic device 1000 at the resonance frequency point corresponding to the first sub-resonance mode a is improved.

Referring to fig. 20 and 21, the first rf front-end unit 61 further includes a first fm circuit T1. In an embodiment, the first frequency modulation circuit T1 is used for matching adjustment, specifically, one end of the first frequency modulation circuit T1 is electrically connected to the first frequency modulation filter circuit M1, and the other end of the first frequency modulation circuit T1 is grounded. In another embodiment, the first frequency modulation circuit T1 is used for caliber adjustment, and one end of the first frequency modulation circuit T1 is electrically connected between the first ground terminal G1 and the first feeding point a, and the other end of the first frequency modulation circuit T1 is grounded. In the above two connection modes, the first fm circuit T1 is configured to adjust the resonance frequency of the first sub-resonant mode a by adjusting the impedance of the first radiator 11.

In an embodiment, the first frequency modulation circuit T1 includes, but is not limited to, a capacitor, an inductor, a resistor, etc. arranged in series and/or parallel, and the first frequency modulation circuit T1 may include a plurality of branches formed by the capacitor, the inductor, the resistor, etc. connected in series and/or parallel, and a switch for controlling the on/off of the plurality of branches. The on-off of different switches is controlled, so that the frequency selection parameters (including resistance value, inductance value and capacitance value) of the first frequency modulation circuit T1 can be adjusted, and then the impedance of the first radiator 11 is adjusted, and the resonance frequency point of the first sub-resonance mode a is adjusted.

Specifically, the resonance frequency point corresponding to the first sub-resonance mode a is located between 1900 and 2000 MHz. When the electronic device 1000 needs to transmit and receive electromagnetic wave signals between 1900MHz and 2000MHz, the frequency modulation parameters (e.g. resistance, capacitance, inductance) of the first frequency modulation circuit T1 are adjusted to make the first antenna unit 10 operate in the first sub-resonance mode a. When the electronic device 1000 needs to transmit and receive electromagnetic wave signals between 1800 MHz and 1900MHz, the frequency modulation parameters (e.g. resistance, capacitance, inductance) of the first frequency modulation circuit T1 are further adjusted, so that the resonance frequency point of the first sub-resonance mode a shifts towards the low frequency band. When the electronic device 1000 needs to transmit and receive electromagnetic wave signals between 2000MHz and 2100MHz, the frequency modulation parameters (e.g., resistance, capacitance, inductance) of the first frequency modulation circuit T1 are further adjusted, so that the resonance frequency point of the first sub-resonance mode a shifts towards the high frequency band. In this way, frequency coverage of the first antenna unit 10 in a wider frequency band can be achieved by adjusting the frequency modulation parameters of the first frequency modulation circuit T1.

The specific structure of the first frequency modulation circuit T1 is not specifically limited, and the adjustment mode thereof is not specifically limited.

In another embodiment, the first frequency modulation circuit T1 includes, but is not limited to, a variable capacitor. The capacitance value of the variable capacitor is adjusted to adjust the frequency modulation parameter of the first frequency modulation circuit T1, and further adjust the impedance of the first radiator 11 to adjust the resonance frequency point of the first sub-resonance mode a.

The first antenna element 10 operates in the fundamental mode of the first coupling segment R1 to produce a second sub-resonant mode b. The resonance frequency point of the second sub-resonance mode b is greater than the resonance frequency point of the first sub-resonance mode a. Specifically, when the first excitation signal generated by the first signal source 12 acts between the second coupling end H2 and the first coupling point C', a second sub-resonance mode b is generated, and the resonance frequency point corresponding to the second sub-resonance mode b has higher efficiency, so that the communication quality of the electronic device 1000 at the resonance frequency point corresponding to the second sub-resonance mode b is improved.

Referring to fig. 4 and 20, the second rf front-end unit 62 further includes a second fm circuit M2'. The second frequency modulation circuit M2 ' is used for caliber adjustment, specifically, one end of the second frequency modulation circuit M2 ' is electrically connected with the first coupling point C ', and one end of the second frequency modulation circuit M2 ' far away from the first coupling point C ' is used for grounding. The second frequency modulation circuit M2' adjusts the resonance frequency point of the second sub-resonance mode b by adjusting the impedance of the first coupling segment R1.

In an embodiment, the second frequency modulation circuit M2 'includes, but is not limited to, a capacitor, an inductor, a resistor, etc. arranged in series and/or parallel, and the second frequency modulation circuit M2' may include a plurality of branches formed by the capacitor, the inductor, the resistor, etc. connected in series and/or parallel, and a switch for controlling the on/off of the plurality of branches. The frequency selection parameters (including resistance value, inductance value and capacitance value) of the second frequency modulation circuit M2' can be adjusted by controlling the on-off of different switches, so as to adjust the impedance of the first coupling section R1, and further enable the first antenna unit 10 to transmit and receive electromagnetic wave signals of the resonance frequency point of the second sub-resonance mode b or nearby resonance frequency points.

Specifically, the resonance frequency point corresponding to the second sub-resonance mode b is between 2600 and 2700 MHz. When the electronic device 1000 needs to transmit and receive the electromagnetic wave signal between 2600MHz and 2700MHz, the frequency modulation parameters (e.g. resistance, capacitance, inductance) of the second frequency modulation circuit M2' are adjusted to make the first antenna unit 10 operate in the second sub-resonance mode b. When the electronic device 1000 needs to transmit and receive electromagnetic wave signals between 2500 MHz and 2600MHz, the frequency modulation parameters (e.g. resistance, capacitance, inductance) of the second frequency modulation circuit M2' are further adjusted, so that the resonance frequency point of the second sub-resonance mode b is shifted towards the low frequency band. When the electronic device 1000 needs to transmit and receive electromagnetic wave signals between 2700MHz and 2800MHz, frequency modulation parameters (e.g., resistance, capacitance, inductance) of the second frequency modulation circuit M2' are further adjusted, so that a resonance frequency point of the second sub-resonance mode b shifts toward the high frequency band. Thus, frequency coverage of the first antenna unit 10 in a wider frequency band can be achieved by adjusting the tuning parameters of the second tuning circuit M2'.

The specific structure of the second frequency modulation circuit M2' is not specifically limited, and the adjustment mode thereof is not specifically limited.

In another embodiment, the second frequency modulation circuit M2' includes, but is not limited to, a variable capacitor. The capacitance value of the variable capacitor is adjusted to adjust the frequency modulation parameter of the second frequency modulation circuit M2', so as to adjust the impedance of the first coupling section R1 and adjust the resonance frequency point of the second sub-resonance mode b.

The first antenna element 10 operates in the fundamental mode from the first feed point a to the first coupling end H1 to generate a third sub-resonant mode c. The resonance frequency point of the third sub-resonance mode c is greater than the resonance frequency point of the third sub-resonance mode c.

Specifically, when the first excitation signal generated by the first signal source 12 acts between the first feeding point a and the first coupling end H1, a third sub-resonance mode c is generated, and the resonant frequency point corresponding to the third sub-resonance mode c has higher transceiving efficiency, so that the communication quality of the electronic device 1000 at the resonant frequency point corresponding to the third sub-resonance mode c is improved.

Referring to fig. 4 and 22, the second radiator 21 further includes a first tuning point B. The first frequency modulation point B is located between the second coupling end H2 and the first coupling point C'. The first isolation device 71 comprises a second isolation capacitor C4. One end of the second isolation capacitor C4 is electrically connected to the first frequency modulation point B. The second isolation capacitor C4 is used for isolating the first induction signal at the first frequency modulation point B.

The first rf front-end unit 61 further comprises a third frequency modulation circuit T2. In an embodiment, the third frequency modulation circuit T2 is used for caliber adjustment, specifically, one end of the third frequency modulation circuit T2 is electrically connected to the other end of the second isolation capacitor C4, and the other end of the third frequency modulation circuit T2 is grounded. In another embodiment, the third frequency modulation circuit T2 is used for matching adjustment, specifically, one end of the third frequency modulation circuit T2 is electrically connected to the second frequency modulation circuit M2', and the other end of the third frequency modulation circuit T2 is grounded. The third frequency modulation circuit T2 is configured to adjust a resonance frequency point of the second sub-resonance mode b and a resonance frequency point of the third sub-resonance mode c.

The third frequency modulation circuit T2 adjusts the resonance frequency point of the third sub-resonance mode C by adjusting the impedance of the portion of the first radiator 11 between the second coupling end H2 and the first coupling point C'.

In an embodiment, the third frequency modulation circuit T2 includes, but is not limited to, a capacitor, an inductor, a resistor, etc. arranged in series and/or parallel, and the third frequency modulation circuit T2 may include a plurality of branches formed by the capacitor, the inductor, the resistor, etc. connected in series and/or parallel, and a switch for controlling the on/off of the plurality of branches. The frequency selection parameters (including resistance, inductance and capacitance) of the third frequency modulation circuit T2 can be adjusted by controlling the on-off of different switches, so as to adjust the impedance of the part of the first radiator 11 between the second coupling end H2 and the first coupling point C', and further enable the first antenna unit 10 to transmit and receive electromagnetic wave signals of the resonance frequency point of the third sub-resonance mode C or the nearby resonance frequency point.

Specifically, the resonance frequency point corresponding to the third sub-resonance mode c is located between 3800MHz and 3900 MHz. When the electronic device 1000 needs to transmit/receive the electromagnetic wave signal between 3800MHz and 3900MHz, the frequency modulation parameter (e.g. resistance, capacitance, inductance) of the third frequency modulation circuit T2 is adjusted, so that the first antenna unit 10 operates in the third sub-resonance mode c. When the electronic device 1000 needs to transmit and receive the electromagnetic wave signal between 3700 MHz and 3800MHz, the frequency modulation parameter (e.g. resistance value, capacitance value, inductance value) of the third frequency modulation circuit T2 is further adjusted, so that the resonance frequency point of the electromagnetic wave signal of the third sub-resonance mode c is shifted towards the low frequency band. When the electronic device 1000 needs to transmit and receive electromagnetic wave signals between 3900MHz and 4000MHz, the frequency modulation parameters (e.g. resistance, capacitance, inductance) of the third frequency modulation circuit T2 are further adjusted, so that the resonance frequency point of the electromagnetic wave signal of the third sub-resonance mode c shifts towards the high frequency band. In this way, frequency coverage of the first antenna unit 10 in a wider frequency band can be achieved by adjusting the tuning parameters of the third tuning circuit T2.

The specific structure of the third frequency modulation circuit T2 is not specifically limited, and the adjustment mode thereof is not specifically limited.

In another embodiment, the third frequency modulation circuit T2 includes, but is not limited to, a variable capacitor. The capacitance value of the variable capacitor is adjusted to adjust the frequency modulation parameter of the third frequency modulation circuit T2, so as to adjust the impedance of a part of the first radiator 11 between the second coupling end H2 and the first coupling point C', thereby adjusting the resonance frequency point of the third sub-resonance mode C.

The first antenna element 10 operates in the 3-order modes from the first ground G1 to the first coupling H1 to generate a fourth sub-resonance mode d.

Specifically, when the first excitation signal generated by the first signal source 12 acts between the first feeding point a and the first coupling end H1, a fourth sub-resonance mode d is further generated, and the resonant frequency point corresponding to the fourth sub-resonance mode d has higher transceiving efficiency, so that the communication quality of the electronic device 1000 at the resonant frequency point corresponding to the fourth sub-resonance mode d is improved. The resonance frequency point of the fourth sub-resonance mode d is greater than the resonance frequency point of the third sub-resonance mode c. Similarly, the third frequency modulation circuit T2 may adjust the resonance frequency point corresponding to the fourth sub-resonance mode d.

Optionally, the second feeding point C is a first coupling point C'. The second frequency modulation circuit M2' may be a second frequency modulation filter circuit M2. In this way, the first coupling point C 'is used as the second feeding point C, so that the first coupling point C' can be used as the feeding of the second antenna unit 20 or as the coupling antenna unit with the first antenna unit 10, and the structural compactness of the antenna is increased. Of course, in other embodiments, the second feeding point C may be disposed between the first coupling point C' and the third coupling end H3.

The second excitation signal generated by the second signal source 22 is filtered and adjusted by the second frequency modulation circuit M2', and then acts between the first frequency modulation point B and the third coupling end H3 to generate a second resonance mode.

Further, referring to fig. 4 and 22, the second radiator 21 further includes a second tuning point D. The second tuning point D is located between the second feeding point C and the third coupling end H3. The first isolation device 71 includes a third isolation capacitor C5. One end of the third isolation capacitor C5 is electrically connected to the second tuning point D. The third isolation capacitor C5 is used for isolating the first induction signal at the second frequency modulation point D.

The second rf front-end unit 62 further includes a fourth frequency modulation circuit T3. In an embodiment, the fourth frequency modulation circuit T3 is used for caliber adjustment, specifically, one end of the fourth frequency modulation circuit T3 is electrically connected to the other end of the third isolation capacitor C5, and the other end of the fourth frequency modulation circuit T3 is grounded.

Referring to fig. 23, in another embodiment, one end of the second frequency modulation circuit M2 'is electrically connected to the second frequency modulation circuit M2', and the other end of the fourth frequency modulation circuit T3 is grounded. The fourth frequency modulation circuit T3 is configured to adjust a resonance frequency point of the second resonance mode by adjusting an impedance between the first frequency modulation point B and the third coupling end H3.

The length between the first tuning point B and the third coupling end H3 may be about one-fourth of the wavelength of the electromagnetic wave in the second frequency band, so that the second antenna unit 20 has a higher radiation efficiency.

In addition, the first frequency modulation point B is grounded, the first coupling point C' is the second feeding point C, so that the second antenna unit 20 is an inverted-F antenna, and the impedance matching of the second antenna unit 20 can be conveniently adjusted by adjusting the position of the second feeding point C.

In an embodiment, the fourth frequency modulation circuit T3 includes, but is not limited to, a capacitor, an inductor, a resistor, etc. arranged in series and/or parallel, and the fourth frequency modulation circuit T3 may include a plurality of branches formed by the capacitor, the inductor, the resistor, etc. connected in series and/or parallel, and a switch for controlling the on/off of the plurality of branches. The on-off of the different switches is controlled, so that the frequency selection parameters (including resistance value, inductance value and capacitance value) of the fourth frequency modulation circuit T3 can be adjusted, and then the impedance of the part of the second radiator 21 between the first frequency modulation point B and the third coupling end H3 is adjusted, so that the second antenna unit 20 receives and transmits electromagnetic wave signals of the resonance frequency point of the second resonance mode or nearby resonance frequency points.

In an embodiment, referring to fig. 14, when the electronic device 1000 needs to transmit/receive electromagnetic wave signals between 700 MHz and 750MHz, the frequency modulation parameters (e.g. resistance, capacitance, inductance) of the fourth frequency modulation circuit T3 are adjusted to make the second antenna unit 20 operate in the second resonant mode. When the electronic device 1000 needs to transmit and receive electromagnetic wave signals between 500 MHz and 600MHz, the frequency modulation parameters (e.g. resistance, capacitance, inductance) of the fourth frequency modulation circuit T3 are further adjusted, so that the resonance frequency point of the third sub-vibration mode shifts towards the low frequency band. When the electronic device 1000 needs to transmit and receive electromagnetic wave signals between 800 MHz and 900MHz, the frequency modulation parameters (e.g. resistance, capacitance, inductance) of the fourth frequency modulation circuit T3 are further adjusted, so that the resonance frequency point of the second resonance mode shifts towards the high frequency band. In this way, frequency coverage of the second antenna unit 20 in a wider frequency band can be achieved by adjusting the frequency modulation parameters of the fourth frequency modulation circuit T3.

The specific structure of the fourth frequency modulation circuit T3 is not specifically limited, and the adjustment mode thereof is not specifically limited.

In another embodiment, the fourth frequency modulation circuit T3 includes, but is not limited to, a variable capacitor. The capacitance value of the variable capacitor is adjusted to adjust the frequency modulation parameter of the fourth frequency modulation circuit T3, so as to adjust the impedance of the part of the second radiator 21 between the first frequency modulation point B and the third coupling end H3, thereby adjusting the resonance frequency point of the second resonance mode.

The second frequency modulation point D is located when the first coupling point C' is close to the third coupling end H3. Therefore, a second coupling segment R2 is formed between the second tuning point D and the third coupling end H3. The second coupling segment R2 is coupled with the third radiator 31 through the second slot 102 to generate a sixth sub-resonance mode f, a seventh sub-resonance mode g.

As can be seen from the above, the parameters of the frequency modulation circuit and the frequency modulation circuit are set to be adjusted, so that the first antenna unit 10 can be fully covered in the middle-high frequency band and the ultra-high frequency band, the second antenna unit 20 can be fully covered in the low frequency band, and the third antenna unit 30 can be fully covered in the middle-high frequency band and the ultra-high frequency band, thereby realizing the full coverage of the antenna assembly 100 among the low frequency band, the middle-high frequency band and the ultra-high frequency band, and realizing the enhancement of the communication function; the radiator multiplexing between the antenna units can make the overall size of the antenna assembly 100 smaller, promoting miniaturization of the whole machine.

It will be appreciated that, in the above embodiment, the specific structure of the first isolation device 71 is enumerated, and the third isolation device 73 of the first antenna unit 10 and the fifth isolation device 75 of the third antenna unit 30 may refer to the first isolation device 71 of the second antenna unit 20.

In an embodiment, referring to fig. 2 and 24, a portion of the antenna assembly 100 is integrated on the housing 500, and specifically, the reference ground 40, the signal source, and the frequency modulation circuit of the antenna assembly 100 are disposed on the motherboard 200. The first radiator 11, the second radiator 21 and the third radiator 31 are integrated as a part of the housing 500. Further, the housing 500 includes a middle frame 501 and a battery cover 502. The display 300, the middle frame 501 and the battery cover 502 are sequentially connected in a covering manner. The first radiator 11, the second radiator 21 and the third radiator 31 are embedded on the middle frame 501 to form a part of the middle frame 501.

Optionally, referring to fig. 24 and 25, the middle frame 501 includes a plurality of metal segments 503 and an insulating segment 504 that separates two adjacent metal segments 503. The multi-section metal section 503 forms the third radiator 31 by the first radiator 11 and the second radiator 21, the insulation section 504 between the first radiator 11 and the second radiator 21 is the first slit 101, and the insulation section 504 between the second radiator 21 and the third radiator 31 is the second slit 102. Alternatively, the first radiator 11, the second radiator 21, and the third radiator 31 are embedded on the battery cover 502 to form a part of the battery cover 502.

Optionally, when the first radiator 11, the second radiator 21 and the third radiator 31 are embedded on the middle frame 501 to form a part of the middle frame 501, the surfaces of the first radiator 11, the second radiator 21 and the third radiator 31 may be covered with a film layer with insulation and higher transmittance of corresponding electromagnetic waves. The first radiator 11, the second radiator 21 and the third radiator 31 can be made to be closer to the main body to be detected, so that the detection accuracy is improved, and the first radiator 11, the second radiator 21 and the third radiator 31 can be insulated from the main body to be detected.

In another embodiment, referring to fig. 26, the antenna assembly 100 is disposed in a housing 500. The reference ground 40, the signal source and the frequency modulation circuit of the antenna assembly 100 are disposed on the motherboard 200. The first radiator 11, the second radiator 21, and the third radiator 31 may be formed on a flexible circuit board and attached to an inner surface of the case 500.

Referring to fig. 25, the housing 500 includes a first side 51, a second side 52, a third side 53, and a fourth side 54, which are connected end to end in sequence. The first side 51 is disposed opposite the third side 53. The second side 52 is disposed opposite the fourth side 54. The length of the first edge 51 is smaller than the length of the second edge 52. The junction of two adjacent sides forms a corner of the housing 500.

In one embodiment, referring to fig. 25, a portion of the first radiator 11 and the second radiator 21 is disposed at or near the first side 51, and another portion of the second radiator 21 and the third radiator 31 is disposed at or near the second side 52. Specifically, the first radiator 11 is disposed on the first side 51 of the housing 500 or along the first side 51. The second radiator 21 is provided at the first side 51, the second side 52 and the corners therebetween. The third radiator 31 is provided at the second side 52 of the housing 500 or along the second side 52.

The electronic device 1000 also includes a controller (not shown). The controller is configured to adjust power of at least one of the first antenna unit 10, the second antenna unit 20, and the third antenna unit 30 according to the proximity state between the subject to be measured and the second radiator 21 detected by the first proximity sensing device 81. Specifically, the controller is further configured to control the power of the second antenna unit 20 to decrease when the distance between the main body to be measured and the second radiator 21 is smaller than a preset threshold, so as to reduce the specific absorption rate of the main body to be measured to electromagnetic waves. The preset threshold is, for example, within 0-5 cm. The specific value of the power reduction of the second antenna element 20 is not specifically limited in this application, and may be reduced to 80%, 60%, 50% of the rated power, or even the second antenna element 20 is turned off. The controller is further configured to control the power of the second antenna unit 20 to increase when the distance between the main body to be measured and the second radiator 21 is greater than a preset threshold value, so as to improve the communication quality of the antenna assembly 100. The specific value of the power reduction of the second antenna element 20 is not specifically limited, and is, for example, restored to the rated power.

Specifically, when the main body to be measured approaches the first radiator 11, the controller is further configured to control the power of the first antenna unit 10 to decrease and control the power of the third antenna unit 30 to increase, so as to reduce the specific absorption rate of the main body to be measured to electromagnetic waves and ensure the communication quality of the antenna assembly 100; the controller is further configured to control the power of the third antenna unit 30 to decrease and control the power of the first antenna unit 10 to increase when the main body to be measured approaches the third radiator 31, thereby reducing the specific absorption rate of the main body to be measured to electromagnetic waves and ensuring the communication quality of the antenna assembly 100.

Further, when the user holds the electronic device 1000 in the vertical direction, the first side 51 is a side far from the ground, and the third side 53 is a side near the ground. When the user makes a call, the user's head is close to the first edge 51. The controller controls the power of the first antenna unit 10 to decrease and controls the power of the third antenna unit 30 to increase when the user's head is close to the first edge 51 to answer a call. The controller can control the third antenna unit 30 arranged on the second side 52 to mainly transmit and receive electromagnetic waves with medium-high frequency and ultrahigh frequency, and can reduce the transmitting and receiving power of the electromagnetic waves near the head of the main body to be tested, thereby reducing the specific absorption rate of the main body to be tested to the electromagnetic waves.

The controller is used for controlling the power of the first antenna unit 10 to be greater than the power of the third antenna unit 30 when the display screen 300 is in the portrait display state. Specifically, when the display screen 300 is in the vertical screen display state or the user holds the electronic device 1000 in the vertical direction, the finger generally shields the second side 52 and the fourth side 54, and at this time, the controller may control the first antenna unit 10 disposed on the first side 51 to mainly transmit and receive the electromagnetic wave with the medium-high frequency and the ultrahigh frequency, so as to avoid that the third antenna unit 30 disposed on the second side 52 is shielded by the finger and cannot transmit and receive the electromagnetic wave with the medium-high frequency and the ultrahigh frequency, thereby affecting the medium-high frequency and the ultrahigh frequency communication quality of the electronic device 1000.

The controller is further configured to control the power of the third antenna element 30 to be greater than the power of the first antenna element 10 when the display screen 300 is in the landscape display state. Specifically, when the display screen 300 is in the landscape display state or the user holds the electronic device 1000 in the horizontal direction, the finger generally shields the first side 51 and the third side 53, and at this time, the controller may control the third antenna unit 30 disposed on the second side 52 to mainly transmit and receive the electromagnetic wave with the medium-high frequency and the ultrahigh frequency, so as to avoid that the first antenna unit 10 disposed on the first side 51 is shielded by the finger and cannot transmit and receive the electromagnetic wave with the medium-high frequency and the ultrahigh frequency, which affects the medium-high frequency and the ultrahigh frequency communication quality of the electronic device 1000.

In another embodiment, referring to fig. 27, the first antenna unit 10, the second antenna unit 20, and the third antenna unit 30 are all disposed on the same side of the housing 500.

While the foregoing is directed to embodiments of the present application, it will be appreciated by those of ordinary skill in the art that numerous modifications and variations can be made without departing from the principles of the present application, and such modifications and variations are also considered to be within the scope of the present application.

Claims (17)

1. An antenna assembly, comprising:

the antenna comprises a first antenna unit, a second antenna unit and a first radio frequency front end unit, wherein the first antenna unit is used for generating a plurality of first resonance modes and is used for receiving and transmitting electromagnetic wave signals of a first frequency band and comprises a first radiator and a first radio frequency front end unit electrically connected with the first radiator; the first radiator comprises a first grounding end, a first feed point and a first coupling end which are sequentially arranged, and the first grounding end is used for grounding;

the second antenna unit is used for receiving and transmitting electromagnetic wave signals of a second frequency band, the maximum value of the second frequency band is smaller than the minimum value of the first frequency band, the second antenna unit comprises a second radiator, a second radio frequency front end unit and at least one first isolation device, and the first isolation device is electrically connected between the second radiator and the second radio frequency front end unit and used for isolating a first induction signal generated when a main body to be detected is close to the second radiator and conducting the electromagnetic wave signals of the second frequency band; the second radiator comprises a second coupling end and a first coupling point, a first gap is formed between the second coupling end and the first coupling end, and the second radiator is capacitively coupled with the first radiator through the first gap; the first coupling point is positioned at one side of the second coupling end away from the first coupling end; the first coupling point is grounded through the first isolation device, a first coupling section is formed between the first coupling point and the second coupling end, and the first coupling section is used for carrying out capacitive coupling with the first radiator; the first resonant mode includes a fundamental mode operating between the first coupling segments;

One end of the second isolation device is electrically connected between the second radiator and the first isolation device or electrically connected with the second radiator, and the second isolation device is used for isolating electromagnetic wave signals of the second frequency band and conducting the first induction signals;

the first proximity sensing device is electrically connected to the other end of the second isolation device and is used for sensing the magnitude of the first induction signal; a kind of electronic device with high-pressure air-conditioning system

The third antenna unit is used for generating a plurality of third resonance modes so as to transmit and receive electromagnetic wave signals of a third frequency band, the minimum value of the third frequency band is larger than the maximum value of the second frequency band, the third antenna unit comprises a third radiator, the third radiator is positioned at one end of the second radiator far away from the first radiator and forms a second gap with the second radiator, and the third radiator and the second radiator are capacitively coupled through the second gap; at least one of the third resonant modes is created by capacitive coupling of the second radiator with the third radiator.

2. The antenna assembly of claim 1, wherein the second antenna element is configured to generate at least one second resonant mode, at least one of the first resonant modes being formed by capacitive coupling of the first radiator with the second radiator.

3. The antenna assembly of claim 2, wherein the minimum value of the first frequency band is greater than or equal to 1000MHz, the maximum value of the second frequency band is less than 1000MHz, and the minimum value of the third frequency band is greater than or equal to 1000MHz.

4. An antenna assembly according to any one of claims 1 to 3, wherein the first isolation device comprises an isolation capacitor and the second isolation device comprises an isolation inductor.

5. The antenna assembly according to any one of claims 1 to 4, wherein the first antenna unit further comprises a third isolation device electrically connected between the first radiator and the first rf front-end unit, for isolating a second induction signal generated when the subject to be tested approaches the first radiator and an electromagnetic wave signal conducting the first frequency band.

6. The antenna assembly of claim 5 wherein the second inductive signal is used to cause the second radiator to generate a sub-inductive signal by coupling of the first radiator to the second radiator, the first proximity sensing device further being used to sense a magnitude of the sub-inductive signal.

7. The antenna assembly of claim 6, further comprising a fourth isolation device, one end of the fourth isolation device being electrically connected between the first radiator and the third isolation device or electrically connected to the first radiator for isolating electromagnetic wave signals of the first frequency band and conducting the second induction signal, and the other end of the fourth isolation device being for outputting the second induction signal.

8. The antenna assembly of claim 7, further comprising a second proximity sensing device electrically connected to the other end of the fourth isolation device for sensing a magnitude of the second inductive signal.

9. The antenna assembly of claim 7, wherein the other end of the fourth isolation device is electrically connected to the first proximity sensing device, the first radiator generating a coupling-induced signal when capacitively coupled to the second radiator, the first proximity sensing device further configured to sense an amount of change in the coupling-induced signal when the subject to be measured is proximate to the first radiator and/or the second radiator.

10. An antenna assembly according to any one of claims 2 to 3, wherein the first rf front end further comprises a first signal source and a first fm filter circuit; one end of the first frequency modulation filter circuit is electrically connected with the first feed point, and the other end of the first frequency modulation filter circuit is electrically connected with the first signal source; the first frequency modulation filter circuit is used for filtering clutter in radio frequency signals transmitted by the first signal source.

11. The antenna assembly of claim 10, wherein the plurality of first resonant modes includes a first sub-resonant mode, a second sub-resonant mode, a third sub-resonant mode, and a fourth sub-resonant mode;

the first antenna unit generates the first sub-resonance mode when working from the first grounding end to the base mode of the first coupling end;

the first antenna element generates the second sub-resonant mode when operating in the fundamental mode of the first coupling segment; the first antenna unit generates the third sub-resonance mode when working from the first feed point to the fundamental mode of the first coupling end;

the first antenna unit generates the fourth sub-resonance mode when working in the 3-time mode from the first grounding end to the first coupling end;

The resonant frequency of the first sub-resonant mode, the resonant frequency of the second sub-resonant mode, the resonant frequency of the third sub-resonant mode and the resonant frequency of the fourth sub-resonant mode are sequentially increased.

12. The antenna assembly of claim 11, wherein the first radio frequency front end unit further comprises a first frequency modulation circuit, one end of the first frequency modulation circuit is electrically connected to the first frequency modulation filter circuit, and the other end of the first frequency modulation circuit is grounded; and/or one end of the first frequency modulation circuit is electrically connected between the first grounding end and the first feed point, the other end of the first frequency modulation circuit is grounded, and the first frequency modulation circuit is used for adjusting the resonance frequency of the first sub-resonance mode; and/or the number of the groups of groups,

the second radio frequency front end unit further comprises a second frequency modulation circuit, the second frequency modulation circuit is electrically connected with the first coupling point, one end, away from the first coupling point, of the second frequency modulation circuit is used for grounding, and the second frequency modulation circuit is used for adjusting the resonance frequency of the second sub-resonance mode; and/or the number of the groups of groups,

the second radiator further comprises a first frequency modulation point, and the first frequency modulation point is located between the second coupling end and the first coupling point; the second radio frequency front end unit further comprises a third frequency modulation circuit, one end of the third frequency modulation circuit is electrically connected with the first isolation device and/or the second frequency modulation circuit, and the other end of the third frequency modulation circuit is grounded; the third frequency modulation circuit is used for adjusting the resonance frequency of the second sub-resonance mode and the resonance frequency of the third sub-resonance mode.

13. The antenna assembly of claim 12, wherein the second radiator further comprises a second feed point and a third coupling end; the third coupling end and the second coupling end are opposite ends of the second radiator, and the second feed point is located between the second coupling end and the third coupling end; wherein the second feed point is the first coupling point;

the second radio frequency front end unit further comprises a second signal source and a second frequency modulation filter circuit, the second frequency modulation filter circuit is the second frequency modulation circuit, the second signal source is electrically connected with one end of the second frequency modulation filter circuit, which is far away from the second feed point, and the second frequency modulation filter circuit is used for filtering clutter of radio frequency signals transmitted by the second signal source;

the second antenna unit generates the second resonance mode when working from the first frequency modulation point to the fundamental mode of the third coupling end.

14. The antenna assembly of claim 13, wherein the second radiator further comprises a second frequency modulation point; the second frequency modulation point is positioned between the second feed point and the third coupling end;

the second radio frequency front end unit further comprises a fourth frequency modulation circuit, one end of the fourth frequency modulation circuit is electrically connected with the first isolation device and/or the second frequency modulation circuit, and the other end of the fourth frequency modulation circuit is grounded; the fourth frequency modulation circuit is used for adjusting the resonance frequency point of the second resonance mode.

15. An electronic device comprising a controller and an antenna assembly according to any one of claims 1 to 14, wherein the controller is configured to adjust power of at least one of the first antenna unit, the second antenna unit, and the third antenna unit according to a state in which the first proximity sensing device detects proximity between the subject to be tested and the second radiator.

16. The electronic device of claim 15, wherein the controller is to control the power of the second antenna unit to decrease when a distance between the subject to be measured and the second radiator is less than or equal to a preset threshold, and to control the power of the second antenna unit to increase when the distance between the subject to be measured and the second radiator is greater than the preset threshold.

17. The electronic device of claim 15, further comprising a housing comprising a first side, a second side, a third side, and a fourth side connected end-to-end in sequence, the first side disposed opposite the third side, the second side disposed opposite the fourth side, the first side having a length less than a length of the second side, a portion of the first and second radiators disposed at or near the first side, and another portion of the second and third radiators disposed at or near the second side; or the first radiator, the second radiator and the third radiator are all arranged on or close to the same side of the shell;

The controller is further used for controlling the power of the first antenna unit to be reduced and controlling the power of the third antenna unit to be increased when the main body to be detected is close to the first radiator; and the device is used for controlling the power of the third antenna unit to be reduced and controlling the power of the first antenna unit to be increased when the main body to be measured is close to the third radiator.